RU2012101096A - AERODYNAMIC SHOVEL FOR AXIAL TURBO MACHINE - Google Patents

Abstract

1. A blade (30) with an aerodynamic profile, having in the radial direction an inner flange region (32) and an outer crown region (34), and in the axial direction - a front leading edge (35) and a trailing trailing edge (36) located between the flange area (32) and coronal region (34) in the radial direction, while the blade (30) is equipped with a trough (38), concave in the radial direction between the inner shelf region (32) and the outer coronal region (34), as well as the back (40 ), convex in the radial direction between the inner flange region (32) and the outer crown region (34), characterized in that the width (W) of the blade (30) in the axial direction between the leading edge (35) and the straight trailing edge (36) changes parabolically from the maximum width (W) in the posterior and coronal regions (32, 34) to the minimum width (W) in the area between the posterior region (32) and the coronal region (34). 2. A blade according to claim 1, characterized in that between the shelf area (32) and the crown area (34) there are variable sections (44) of the airfoil, designed to provide the above-mentioned parabolic change in the width (W) of the blade (30) in the axial direction. ... A blade according to claim 1 or 2, characterized in that the sections (44) of the airfoil located between the shelf region (32) and the crown region (34) have the same angle (B) of installation. A blade according to claim 1 or 2, characterized in that the width (W) of the airfoil blade (30) has a minimum value in the region (42) between the shelf region (32) and the crown region (34). A blade according to claim 4, characterized in that the parabolic change in the width (W) of the blade (30) with an airfoil is symmetric with respect to

Claims (15)

1. A blade (30) with an aerodynamic profile, having in the radial direction the inner flange region (32) and the outer coronal region (34), and in the axial direction - the front inlet edge (35) and the rear outlet edge (36) located between the flange region (32) and the coronal region (34) in the radial direction, while the blade (30) is equipped with a trough (38), concave in the radial direction between the inner shelf region (32) and the outer coronal region (34), as well as the back (40 ) convex in the radial direction between the inner shelf area (32) and the outer coronal region (34), characterized in that the width (W) of the blade (30) in the axial direction between the inlet edge (35) and the straight outlet edge (36) varies parabolic from the maximum width (W _max ) in the flange and crown regions (32, 34) to the minimum width (W _min ) in the area between the shelf region (32) and the coronal region (34). 2. The blade according to claim 1, characterized in that between the shelf region (32) and the coronal region (34) are variable sections (44) of the aerodynamic profile, designed to provide the said parabolic change in the width (W) of the blade (30) in the axial direction . 3. The blade according to claim 1 or 2, characterized in that the sections (44) of the aerodynamic profile located between the shelf region (32) and the crown region (34) have the same installation angle (B). 4. The blade according to claim 1 or 2, characterized in that the width (W _min ) of the blade (30) with an aerodynamic profile has a minimum value in the area (42) between the shelf region (32) and the coronal region (34). 5. The blade according to claim 4, characterized in that the parabolic change in the width (W) of the blade (30) with the aerodynamic profile is symmetrical with respect to the section (42) located in the mid-height part between the shelf region (32) and the crown region (34) . 6. The blade according to claim 1 or 2, characterized in that the value of K, equal to the ratio of the smallest cross section (t) to the step value (p), lies in the range from the minimum values (K _{min platform} ) in the shelf region (32) and (K _{min tip} ) in the coronal region (34), respectively, to the maximum value (K _max ) in the area between the shelf region (32) and the coronal region (34). 7. The blade according to claim 6, characterized in that the minimum value of K in the shelf region (K _{min platform} ) is equal to the minimum value of K in the coronal region (K _{min tip} ). 8. The blade according to claim 1 or 2, characterized in that the value of K reaches a maximum value (K _max ) in the area (42), in the middle-high part, between the shelf region (32) and the coronal region (34). 9. The blade according to claim 1 or 2, characterized in that the value of K varies parabolic and essentially symmetrical with respect to the section (42) located in the mid-height part, between the shelf region (32) and the coronal region (34). 10. The blade according to claim 1 or 2, characterized in that the blade (30) with an aerodynamic profile is a fixed blade of a turbine stage containing a group of the said fixed blades (30). 11. The blade according to claim 1, characterized in that the blade (30) with an aerodynamic profile is designed to be used as one of the blades in a group of similar blades installed in an axial turbomachine having an annular contour for the passage of the working medium. 12. The blade according to claim 1, characterized in that the maximum axial width (W _max ) in the flange and crown regions is essentially the same. 13. The blade according to claim 1, characterized in that the blade with an aerodynamic profile is a stationary blade. 14. An axial turbomachine containing a group of blades (30) with an aerodynamic profile according to any one of the preceding paragraphs. 15. An axial turbomachine according to claim 14, characterized in that the axial turbomachine is a turbine comprising at least one stage of a turbine with stationary turbine blades (30) according to any one of claims 1 to 13.